#include <stdafx.h>

/*
 * pa_win_wmme.c
 * Implementation of PortAudio for Windows MultiMedia Extensions (WMME)
 *
 * PortAudio Portable Real-Time Audio Library
 * Latest Version at: http://www.portaudio.com
 *
 * Authors: Ross Bencina and Phil Burk
 * Copyright (c) 1999-2000 Ross Bencina and Phil Burk
 *
 * Permission is hereby granted, free of charge, to any person obtainingF
 * a copy of this software and associated documentation files
 * (the "Software"), to deal in the Software without restriction,
 * including without limitation the rights to use, copy, modify, merge,
 * publish, distribute, sublicense, and/or sell copies of the Software,
 * and to permit persons to whom the Software is furnished to do so,
 * subject to the following conditions:
 *
 * The above copyright notice and this permission notice shall be
 * included in all copies or substantial portions of the Software.
 *
 * Any person wishing to distribute modifications to the Software is
 * requested to send the modifications to the original developer so that
 * they can be incorporated into the canonical version.
 *
 * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND,
 * EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF
 * MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT.
 * IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR
 * ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF
 * CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION
 * WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
 *
 */
/*
  All memory allocations and frees are marked with MEM for quick review.
*/
/* Modification History:
 PLB = Phil Burk
 PLB20010402 - sDevicePtrs now allocates based on sizeof(pointer)
 PLB20010413 - check for excessive numbers of channels
 PLB20010422 - apply Mike Berry's changes for CodeWarrior on PC
               including condition including of memory.h,
			   and explicit typecasting on memory allocation
 PLB20010802 - use GlobalAlloc for sDevicesPtr instead of PaHost_AllocFastMemory
 PLB20010816 - pass process instead of thread to SetPriorityClass()
 PLB20010927 - use number of frames instead of real-time for CPULoad calculation.
*/
#include <stdio.h>
#include <stdlib.h>
#include <math.h>
#include <windows.h>
#include <mmsystem.h>
#include <process.h>
/* PLB20010422 - "memory.h" doesn't work on CodeWarrior for PC. Thanks Mike Berry for the mod. */
#ifndef __MWERKS__
#include <malloc.h>
#include <memory.h>
#endif /* __MWERKS__ */
#include "portaudio.h"
#include "pa_host.h"
#include "pa_trace.h"
/************************************************* Constants ********/
#define PA_USE_TIMER_CALLBACK    (0)  /* Select between two options for background task. 0=thread, 1=timer */
#define PA_USE_HIGH_LATENCY      (0)  /* For debugging glitches. */
/* Switches for debugging. */
#define PA_SIMULATE_UNDERFLOW    (0)  /* Set to one to force an underflow of the output buffer. */
/* To trace program, enable TRACE_REALTIME_EVENTS in pa_trace.h */
#define PA_TRACE_RUN             (0)
#define PA_TRACE_START_STOP      (1)
#if PA_USE_HIGH_LATENCY
	#define PA_MIN_MSEC_PER_HOST_BUFFER  (100)
	#define PA_MAX_MSEC_PER_HOST_BUFFER  (300) /* Do not exceed unless user buffer exceeds */
	#define PA_MIN_NUM_HOST_BUFFERS      (4)
	#define PA_MAX_NUM_HOST_BUFFERS      (16)  /* OK to exceed if necessary */
	#define PA_WIN_9X_LATENCY            (400)
#else
	#define PA_MIN_MSEC_PER_HOST_BUFFER  (10)
	#define PA_MAX_MSEC_PER_HOST_BUFFER  (100) /* Do not exceed unless user buffer exceeds */
	#define PA_MIN_NUM_HOST_BUFFERS      (3)
	#define PA_MAX_NUM_HOST_BUFFERS      (16)  /* OK to exceed if necessary */
	#define PA_WIN_9X_LATENCY            (200)
#endif
#define MIN_TIMEOUT_MSEC                 (1000)
/*
** Use higher latency for NT because it is even worse at real-time
** operation than Win9x.
*/
#define PA_WIN_NT_LATENCY        (PA_WIN_9X_LATENCY * 2)
#if PA_SIMULATE_UNDERFLOW
static  gUnderCallbackCounter = 0;
#define UNDER_SLEEP_AT       (40)
#define UNDER_SLEEP_FOR      (500)
#endif
#define PRINT(x) { printf x; fflush(stdout); }
#define ERR_RPT(x) PRINT(x)
#define DBUG(x)  /* PRINT(x) */
#define DBUGX(x) /* PRINT(x) */
/************************************************* Definitions ********/
/**************************************************************
 * Structure for internal host specific stream data.
 * This is allocated on a per stream basis.
 */
typedef struct PaHostSoundControl
{
/* Input -------------- */
    HWAVEIN            pahsc_HWaveIn;
    WAVEHDR           *pahsc_InputBuffers;
    int                pahsc_CurrentInputBuffer;
	int                pahsc_BytesPerHostInputBuffer;
	int                pahsc_BytesPerUserInputBuffer;    /* native buffer size in bytes */
/* Output -------------- */    
    HWAVEOUT           pahsc_HWaveOut;
    WAVEHDR           *pahsc_OutputBuffers;
    int                pahsc_CurrentOutputBuffer;
	int                pahsc_BytesPerHostOutputBuffer;
	int                pahsc_BytesPerUserOutputBuffer;    /* native buffer size in bytes */
/* Run Time -------------- */    
	PaTimestamp        pahsc_FramesPlayed;
	long               pahsc_LastPosition;                /* used to track frames played. */
/* For measuring CPU utilization. */
	LARGE_INTEGER      pahsc_EntryCount;
	double             pahsc_InverseTicksPerHostBuffer;
/* Init Time -------------- */    
	int                pahsc_NumHostBuffers;
	int                pahsc_FramesPerHostBuffer;
	int                pahsc_UserBuffersPerHostBuffer;
    CRITICAL_SECTION   pahsc_StreamLock;                  /* Mutext to prevent threads from colliding. */
	INT                pahsc_StreamLockInited;
#if PA_USE_TIMER_CALLBACK
	BOOL               pahsc_IfInsideCallback;            /* Test for reentrancy. */
	MMRESULT           pahsc_TimerID;
#else
    HANDLE             pahsc_AbortEvent;
    int                pahsc_AbortEventInited;
    HANDLE             pahsc_BufferEvent;
    int                pahsc_BufferEventInited;
    HANDLE             pahsc_EngineThread;
    DWORD              pahsc_EngineThreadID;
#endif
} PaHostSoundControl;
/************************************************* Shared Data ********/
/* FIXME - put Mutex around this shared data. */
static int sNumInputDevices = 0;
static int sNumOutputDevices = 0;
static int sNumDevices = 0;
static PaDeviceInfo **sDevicePtrs = NULL;
static int sDefaultInputDeviceID = paNoDevice;
static int sDefaultOutputDeviceID = paNoDevice;
static int sPaHostError = 0;
static const char sMapperSuffixInput[] = " - Input";
static const char sMapperSuffixOutput[] = " - Output";
/************************************************* Macros ********/
/* Convert external PA ID to an internal ID that includes WAVE_MAPPER */
#define PaDeviceIdToWinId(id) (((id) < sNumInputDevices) ? (id - 1) : (id - sNumInputDevices - 1))
/************************************************* Prototypes **********/
static Pa_QueryDevices( void );
static void CALLBACK Pa_TimerCallback(UINT uID, UINT uMsg,
									  DWORD dwUser, DWORD dw1, DWORD dw2);
PaError PaHost_GetTotalBufferFrames( internalPortAudioStream   *past );
static PaError PaHost_UpdateStreamTime( PaHostSoundControl *pahsc );
static PaError PaHost_BackgroundManager( internalPortAudioStream   *past );
/********************************* BEGIN CPU UTILIZATION MEASUREMENT ****/
static void Pa_StartUsageCalculation( internalPortAudioStream   *past )
{
	PaHostSoundControl *pahsc = (PaHostSoundControl *) past->past_DeviceData;
	if( pahsc == NULL ) return;
/* Query system timer for usage analysis and to prevent overuse of CPU. */
	QueryPerformanceCounter( &pahsc->pahsc_EntryCount );
}
static void Pa_EndUsageCalculation( internalPortAudioStream   *past )
{
	LARGE_INTEGER CurrentCount = { 0, 0 };
	PaHostSoundControl *pahsc = (PaHostSoundControl *) past->past_DeviceData;
	if( pahsc == NULL ) return;
/*
** Measure CPU utilization during this callback. Note that this calculation
** assumes that we had the processor the whole time.
*/
#define LOWPASS_COEFFICIENT_0   (0.9)
#define LOWPASS_COEFFICIENT_1   (0.99999 - LOWPASS_COEFFICIENT_0)
	if( QueryPerformanceCounter( &CurrentCount ) )
	{
		LONGLONG InsideCount = CurrentCount.QuadPart - pahsc->pahsc_EntryCount.QuadPart;	
		double newUsage = InsideCount * pahsc->pahsc_InverseTicksPerHostBuffer;
		past->past_Usage = (LOWPASS_COEFFICIENT_0 * past->past_Usage) +
			(LOWPASS_COEFFICIENT_1 * newUsage);
	}
}
/****************************************** END CPU UTILIZATION *******/
static PaError Pa_QueryDevices( void )
{
	int numBytes;
/* Count the devices and add one extra for the WAVE_MAPPER */
    sNumInputDevices = waveInGetNumDevs() + 1;
	sDefaultInputDeviceID = 0;
    sNumOutputDevices = waveOutGetNumDevs() + 1;
	sDefaultOutputDeviceID = sNumInputDevices;
    sNumDevices = sNumInputDevices + sNumOutputDevices;
/* Allocate structures to hold device info. */
/* PLB20010402 - was allocating too much memory. */
/*	numBytes = sNumDevices * sizeof(PaDeviceInfo);  // PLB20010402 */
	numBytes = sNumDevices * sizeof(PaDeviceInfo *); /* PLB20010402 */
	sDevicePtrs = (PaDeviceInfo **) GlobalAlloc( GPTR, numBytes ); /* MEM */
	if( sDevicePtrs == NULL ) return paInsufficientMemory;
	return paNoError;
}
/************************************************************************************/
long Pa_GetHostError()
{
	return sPaHostError;
}
/*************************************************************************/
int Pa_CountDevices()
{
	if( sNumDevices <= 0 ) Pa_Initialize();
	return sNumDevices;
}
/*************************************************************************
** If a PaDeviceInfo structure has not already been created,
** then allocate one and fill it in for the selected device.
**
** We create one extra input and one extra output device for the WAVE_MAPPER.
** [Does anyone know how to query the default device and get its name?]
*/
const PaDeviceInfo* Pa_GetDeviceInfo( PaDeviceID id )
{	
#define NUM_STANDARDSAMPLINGRATES   3   /* 11.025, 22.05, 44.1 */
#define NUM_CUSTOMSAMPLINGRATES     5   /* must be the same number of elements as in the array below */
#define MAX_NUMSAMPLINGRATES        (NUM_STANDARDSAMPLINGRATES+NUM_CUSTOMSAMPLINGRATES)
    static DWORD customSamplingRates[] = { 32000, 48000, 64000, 88200, 96000 };
    PaDeviceInfo *deviceInfo;
    double *sampleRates; /* non-const ptr */
    int i;
    char *s;
    
    if( id < 0 || id >= sNumDevices )
        return NULL;
    if( sDevicePtrs[ id ] != NULL )
	{
        return sDevicePtrs[ id ];
    }
    deviceInfo = (PaDeviceInfo *)GlobalAlloc( GPTR, sizeof(PaDeviceInfo) ); /* MEM */
	if( deviceInfo == NULL ) return NULL;
    deviceInfo->structVersion = 1;
    deviceInfo->maxInputChannels = 0;
    deviceInfo->maxOutputChannels = 0;
    deviceInfo->numSampleRates = 0;
    sampleRates = (double*)GlobalAlloc( GPTR, MAX_NUMSAMPLINGRATES * sizeof(double) ); /* MEM */
    deviceInfo->sampleRates = sampleRates;
    deviceInfo->nativeSampleFormats = paInt16;       /* should query for higher bit depths below */
    if( id < sNumInputDevices )
	{
        /* input device */
        int inputMmID = id - 1; /* WAVE_MAPPER is -1 so we start with WAVE_MAPPER */
        WAVEINCAPS wic;
        if( waveInGetDevCaps( inputMmID, &wic, sizeof( WAVEINCAPS ) ) != MMSYSERR_NOERROR )
            goto error;
        
	/* Append I/O suffix to WAVE_MAPPER device. */
		if( inputMmID == WAVE_MAPPER )
		{
			s = (char *) GlobalAlloc( GMEM_FIXED, strlen( wic.szPname ) + 1 + sizeof(sMapperSuffixInput) ); /* MEM */
			strcpy( s, wic.szPname );
			strcat( s, sMapperSuffixInput );
		}
		else
		{
			s = (char *) GlobalAlloc( GMEM_FIXED, strlen( wic.szPname ) + 1 ); /* MEM */
			strcpy( s, wic.szPname );
		}
        deviceInfo->name = s;
        deviceInfo->maxInputChannels = wic.wChannels;
	/* Sometimes a device can return a rediculously large number of channels.
	** This happened with an SBLive card on a Windows ME box.
	** If that happens, then force it to 2 channels.  PLB20010413
	*/
		if( (deviceInfo->maxInputChannels < 1) || (deviceInfo->maxInputChannels > 256) )
		{
			ERR_RPT(("Pa_GetDeviceInfo: Num input channels reported as %d! Changed to 2.\n", deviceInfo->maxOutputChannels ));
			deviceInfo->maxInputChannels = 2;
		}
	/* Add a sample rate to the list if we can do stereo 16 bit at that rate
	 * based on the format flags. */
        if( wic.dwFormats & WAVE_FORMAT_1M16 ||wic.dwFormats & WAVE_FORMAT_1S16 )
            sampleRates[ deviceInfo->numSampleRates++ ] = 11025.;
        if( wic.dwFormats & WAVE_FORMAT_2M16 ||wic.dwFormats & WAVE_FORMAT_2S16 )
            sampleRates[ deviceInfo->numSampleRates++ ] = 22050.;
        if( wic.dwFormats & WAVE_FORMAT_4M16 ||wic.dwFormats & WAVE_FORMAT_4S16 )
            sampleRates[ deviceInfo->numSampleRates++ ] = 44100.;
	/* Add a sample rate to the list if we can do stereo 16 bit at that rate
	 * based on opening the device successfully. */
        for( i=0; i < NUM_CUSTOMSAMPLINGRATES; i++ ){
            WAVEFORMATEX wfx;
            wfx.wFormatTag = WAVE_FORMAT_PCM;
            wfx.nSamplesPerSec = customSamplingRates[i];
            wfx.wBitsPerSample = 16;
            wfx.cbSize = 0; /* ignored */
            wfx.nChannels = (WORD)deviceInfo->maxInputChannels;
            wfx.nAvgBytesPerSec = wfx.nChannels * wfx.nSamplesPerSec * sizeof(short);
            wfx.nBlockAlign = (WORD)(wfx.nChannels * sizeof(short));
            if( waveInOpen( NULL, inputMmID, &wfx, 0, 0, WAVE_FORMAT_QUERY ) == MMSYSERR_NOERROR )
			{
                sampleRates[ deviceInfo->numSampleRates++ ] = customSamplingRates[i];
            }
        }
        
    }
	else if( id - sNumInputDevices < sNumOutputDevices )
	{
        /* output device */
        int outputMmID = id - sNumInputDevices - 1;
        WAVEOUTCAPS woc;
        if( waveOutGetDevCaps( outputMmID, &woc, sizeof( WAVEOUTCAPS ) ) != MMSYSERR_NOERROR )
            goto error;
	/* Append I/O suffix to WAVE_MAPPER device. */
		if( outputMmID == WAVE_MAPPER )
		{
			s = (char *) GlobalAlloc( GMEM_FIXED, strlen( woc.szPname ) + 1 + sizeof(sMapperSuffixOutput) );  /* MEM */
			strcpy( s, woc.szPname );
			strcat( s, sMapperSuffixOutput );
		}
		else
		{
			s = (char *) GlobalAlloc( GMEM_FIXED, strlen( woc.szPname ) + 1 );  /* MEM */
			strcpy( s, woc.szPname );
		}
        deviceInfo->name = s;
        deviceInfo->maxOutputChannels = woc.wChannels;
	/* Sometimes a device can return a rediculously large number of channels.
	** This happened with an SBLive card on a Windows ME box.
	** If that happens, then force it to 2 channels. PLB20010413
	*/
		if( (deviceInfo->maxOutputChannels < 1) || (deviceInfo->maxOutputChannels > 256) )
		{
			ERR_RPT(("Pa_GetDeviceInfo: Num output channels reported as %d! Changed to 2.\n", deviceInfo->maxOutputChannels ));
			deviceInfo->maxOutputChannels = 2;
		}
	/* Add a sample rate to the list if we can do stereo 16 bit at that rate
	 * based on the format flags. */
        if( woc.dwFormats & WAVE_FORMAT_1M16 ||woc.dwFormats & WAVE_FORMAT_1S16 )
            sampleRates[ deviceInfo->numSampleRates++ ] = 11025.;
        if( woc.dwFormats & WAVE_FORMAT_2M16 ||woc.dwFormats & WAVE_FORMAT_2S16 )
            sampleRates[ deviceInfo->numSampleRates++ ] = 22050.;
        if( woc.dwFormats & WAVE_FORMAT_4M16 ||woc.dwFormats & WAVE_FORMAT_4S16 )
            sampleRates[ deviceInfo->numSampleRates++ ] = 44100.;
	/* Add a sample rate to the list if we can do stereo 16 bit at that rate
	 * based on opening the device successfully. */
        for( i=0; i < NUM_CUSTOMSAMPLINGRATES; i++ )
		{
            WAVEFORMATEX wfx;
            wfx.wFormatTag = WAVE_FORMAT_PCM;
            wfx.nSamplesPerSec = customSamplingRates[i];
            wfx.wBitsPerSample = 16;
            wfx.cbSize = 0; /* ignored */
            wfx.nChannels = (WORD)deviceInfo->maxOutputChannels;
            wfx.nAvgBytesPerSec = wfx.nChannels * wfx.nSamplesPerSec * sizeof(short);
            wfx.nBlockAlign = (WORD)(wfx.nChannels * sizeof(short));
            if( waveOutOpen( NULL, outputMmID, &wfx, 0, 0, WAVE_FORMAT_QUERY ) == MMSYSERR_NOERROR ){
                sampleRates[ deviceInfo->numSampleRates++ ] = customSamplingRates[i];
            }
        }
    }
    sDevicePtrs[ id ] = deviceInfo;
    return deviceInfo;
error:
    GlobalFree( sampleRates ); /* MEM */
    GlobalFree( deviceInfo ); /* MEM */
    
    return NULL;
}
/*************************************************************************
** Returns recommended device ID.
** On the PC, the recommended device can be specified by the user by
** setting an environment variable. For example, to use device #1.
**
**    set PA_RECOMMENDED_OUTPUT_DEVICE=1
**
** The user should first determine the available device ID by using
** the supplied application "pa_devs".
*/
#define PA_ENV_BUF_SIZE  (32)
#define PA_REC_IN_DEV_ENV_NAME  ("PA_RECOMMENDED_INPUT_DEVICE")
#define PA_REC_OUT_DEV_ENV_NAME  ("PA_RECOMMENDED_OUTPUT_DEVICE")
static PaDeviceID PaHost_GetEnvDefaultDeviceID( char *envName )
{
	DWORD   hresult;
	char    envbuf[PA_ENV_BUF_SIZE];
	PaDeviceID recommendedID = paNoDevice;
/* Let user determine default device by setting environment variable. */
	hresult = GetEnvironmentVariable( envName, envbuf, PA_ENV_BUF_SIZE );
	if( (hresult > 0) && (hresult < PA_ENV_BUF_SIZE) )
	{
		recommendedID = atoi( envbuf );
	}
	return recommendedID;
}
static PaError Pa_MaybeQueryDevices( void )
{
	if( sNumDevices == 0 )
	{
		return Pa_QueryDevices();
	}
	return 0;
}
/**********************************************************************
** Check for environment variable, else query devices and use result.
*/
PaDeviceID Pa_GetDefaultInputDeviceID( void )
{
	PaError result;
	result = PaHost_GetEnvDefaultDeviceID( PA_REC_IN_DEV_ENV_NAME );
	if( result < 0 )
	{
		result = Pa_MaybeQueryDevices();
		if( result < 0 ) return result;
		result = sDefaultInputDeviceID;
	}
	return result;
}
PaDeviceID Pa_GetDefaultOutputDeviceID( void )
{
	PaError result;
	result = PaHost_GetEnvDefaultDeviceID( PA_REC_OUT_DEV_ENV_NAME );
	if( result < 0 )
	{
		result = Pa_MaybeQueryDevices();
		if( result < 0 ) return result;
		result = sDefaultOutputDeviceID;
	}
	return result;
}
/**********************************************************************
** Initialize Host dependant part of API.
*/
PaError PaHost_Init( void )
{
#if PA_SIMULATE_UNDERFLOW
	PRINT(("WARNING - Underflow Simulation Enabled - Expect a Big Glitch!!!\n"));
#endif
	return Pa_MaybeQueryDevices();
}
/**********************************************************************
** Check WAVE buffers to see if they are done.
** Fill any available output buffers and use any available
** input buffers by calling user callback.
*/
static PaError Pa_TimeSlice( internalPortAudioStream   *past )
{
	PaError           result = 0;
	long              bytesEmpty = 0;
	long              bytesFilled = 0;
	long              buffersEmpty = 0;
	MMRESULT          mresult;
	char             *inBufPtr;
	char             *outBufPtr;
	int               gotInput = 0;
	int               gotOutput = 0;
	int               i;
	int               buffersProcessed = 0;
	int               done = 0;
	PaHostSoundControl *pahsc = (PaHostSoundControl *) past->past_DeviceData;
	if( pahsc == NULL ) return paInternalError;
	past->past_NumCallbacks += 1;
#if PA_SIMULATE_UNDERFLOW
	if(gUnderCallbackCounter++ == UNDER_SLEEP_AT)
	{
		Sleep(UNDER_SLEEP_FOR);
	}
#endif
#if PA_TRACE_RUN
	AddTraceMessage("Pa_TimeSlice: past_NumCallbacks ", past->past_NumCallbacks );
#endif
	while(!done)
	{
/* If we are using output, then we need an empty output buffer. */
		gotOutput = 0;
		outBufPtr = NULL;
		if( past->past_NumOutputChannels > 0 )
		{
			if((pahsc->pahsc_OutputBuffers[ pahsc->pahsc_CurrentOutputBuffer ].dwFlags & WHDR_DONE) == 0)
			{	
				break;  /* If none empty then bail and try again later. */
			}
			else
			{
				outBufPtr = pahsc->pahsc_OutputBuffers[ pahsc->pahsc_CurrentOutputBuffer ].lpData;
				gotOutput = 1;
			}
		}
/* Use an input buffer if one is available. */
		gotInput = 0;
		inBufPtr = NULL;
		if( ( past->past_NumInputChannels > 0 ) &&
			(pahsc->pahsc_InputBuffers[ pahsc->pahsc_CurrentInputBuffer ].dwFlags & WHDR_DONE) )
		{
			inBufPtr = pahsc->pahsc_InputBuffers[ pahsc->pahsc_CurrentInputBuffer ].lpData;
			gotInput = 1;
#if PA_TRACE_RUN
			AddTraceMessage("Pa_TimeSlice: got input buffer at ", (int)inBufPtr );
			AddTraceMessage("Pa_TimeSlice: got input buffer # ", pahsc->pahsc_CurrentInputBuffer );
#endif
		}
/* If we can't do anything then bail out. */
		if( !gotInput && !gotOutput ) break;
		buffersProcessed += 1;
/* Each Wave buffer contains multiple user buffers so do them all now. */
/* Base Usage on time it took to process one host buffer. */
		Pa_StartUsageCalculation( past );
		for( i=0; i<pahsc->pahsc_UserBuffersPerHostBuffer; i++ )
		{
			if( done )
			{
				if( gotOutput )
				{
		/* Clear remainder of wave buffer if we are waiting for stop. */
					AddTraceMessage("Pa_TimeSlice: zero rest of wave buffer ", i );
					memset( outBufPtr, 0, pahsc->pahsc_BytesPerUserOutputBuffer );
				}
			}
			else
			{
	/* Convert 16 bit native data to user data and call user routine. */
				result = Pa_CallConvertInt16( past, (short *) inBufPtr, (short *) outBufPtr );
				if( result != 0) done = 1;
			}
			if( gotInput ) inBufPtr += pahsc->pahsc_BytesPerUserInputBuffer;
			if( gotOutput) outBufPtr += pahsc->pahsc_BytesPerUserOutputBuffer;
		}
		Pa_EndUsageCalculation( past );
/* Send WAVE buffer to Wave Device to be refilled. */
		if( gotInput )
		{
			mresult = waveInAddBuffer( pahsc->pahsc_HWaveIn,
				&pahsc->pahsc_InputBuffers[ pahsc->pahsc_CurrentInputBuffer ],
				sizeof(WAVEHDR) );
			if( mresult != MMSYSERR_NOERROR )
			{
				sPaHostError = mresult;
				result = paHostError;
				break;
			}
			pahsc->pahsc_CurrentInputBuffer = (pahsc->pahsc_CurrentInputBuffer+1 >= pahsc->pahsc_NumHostBuffers) ?
				0 : pahsc->pahsc_CurrentInputBuffer+1;
		}
/* Write WAVE buffer to Wave Device. */
		if( gotOutput )
		{
#if PA_TRACE_START_STOP
    AddTraceMessage( "Pa_TimeSlice: writing buffer ", pahsc->pahsc_CurrentOutputBuffer );
#endif
			mresult = waveOutWrite( pahsc->pahsc_HWaveOut,
				&pahsc->pahsc_OutputBuffers[ pahsc->pahsc_CurrentOutputBuffer ],
				sizeof(WAVEHDR) );
			if( mresult != MMSYSERR_NOERROR )
			{
				sPaHostError = mresult;
				result = paHostError;
				break;
			}
			pahsc->pahsc_CurrentOutputBuffer = (pahsc->pahsc_CurrentOutputBuffer+1 >= pahsc->pahsc_NumHostBuffers) ?
				0 : pahsc->pahsc_CurrentOutputBuffer+1;
		}
	}
			
#if PA_TRACE_RUN
	AddTraceMessage("Pa_TimeSlice: buffersProcessed ", buffersProcessed );
#endif
	return (result != 0) ? result : done;
}
/*******************************************************************/
static PaError PaHost_BackgroundManager( internalPortAudioStream   *past )
{
	PaError      result = 0;
    int          i;
	int          numQueuedOutputBuffers = 0;
	PaHostSoundControl *pahsc = (PaHostSoundControl *) past->past_DeviceData;
/* Has someone asked us to abort by calling Pa_AbortStream()? */
	if( past->past_StopNow )
	{
        past->past_IsActive = 0; /* Will cause thread to return. */
    }
/* Has someone asked us to stop by calling Pa_StopStream()
 * OR has a user callback returned '1' to indicate finished.
 */
	else if( past->past_StopSoon )
	{
/* Poll buffer and when all have played then exit thread. */
/* Count how many output buffers are queued. */
        numQueuedOutputBuffers = 0;
        if( past->past_NumOutputChannels > 0 )
		{
			for( i=0; i<pahsc->pahsc_NumHostBuffers; i++ )
			{
				if( !( pahsc->pahsc_OutputBuffers[ i ].dwFlags & WHDR_DONE) )
				{
#if PA_TRACE_START_STOP
AddTraceMessage( "WinMMPa_OutputThreadProc: waiting for buffer ", i );
#endif
					numQueuedOutputBuffers++;
				}
			}
		}
#if PA_TRACE_START_STOP
AddTraceMessage( "WinMMPa_OutputThreadProc: numQueuedOutputBuffers ", numQueuedOutputBuffers );
#endif
        if( numQueuedOutputBuffers == 0 )
		{
            past->past_IsActive = 0; /* Will cause thread to return. */
		}
    }
	else
	{
/* Process full input buffer and fill up empty output buffers. */
		if( (result = Pa_TimeSlice( past )) != 0) 
		{
	/* User callback has asked us to stop. */
#if PA_TRACE_START_STOP
AddTraceMessage( "WinMMPa_OutputThreadProc: TimeSlice() returned ", result );
#endif
            past->past_StopSoon = 1; /* Request that audio play out then stop. */
			result = paNoError;
		}
	}
	
	PaHost_UpdateStreamTime( pahsc );
	return result;
}
#if PA_USE_TIMER_CALLBACK
/*******************************************************************/
static void CALLBACK Pa_TimerCallback(UINT uID, UINT uMsg, DWORD dwUser, DWORD dw1, DWORD dw2)
{
	internalPortAudioStream   *past;
	PaHostSoundControl        *pahsc;
	PaError                    result;
	past = (internalPortAudioStream *) dwUser;
	if( past == NULL ) return;
	pahsc = (PaHostSoundControl *) past->past_DeviceData;
	if( pahsc == NULL ) return;
	if( pahsc->pahsc_IfInsideCallback )
	{
		if( pahsc->pahsc_TimerID != 0 )
		{
			timeKillEvent(pahsc->pahsc_TimerID);  /* Stop callback timer. */
			pahsc->pahsc_TimerID = 0;
		}
		return;
	}
	pahsc->pahsc_IfInsideCallback = 1;
/* Manage flags and audio processing. */
 	result = PaHost_BackgroundManager( past );
	if( result != paNoError )
	{
		past->past_IsActive = 0;
	}
	pahsc->pahsc_IfInsideCallback = 0;
}
#else /* PA_USE_TIMER_CALLBACK */
/*******************************************************************/
static DWORD WINAPI WinMMPa_OutputThreadProc( void *pArg )
{
	internalPortAudioStream *past;
 	PaHostSoundControl      *pahsc;
    void        *inputBuffer=NULL;
    HANDLE       events[2];
	int          numEvents = 0;
	DWORD        result = 0;
	DWORD        waitResult;
	DWORD        numTimeouts = 0;
	DWORD        timeOut;
	past = (internalPortAudioStream *) pArg;
	pahsc = (PaHostSoundControl *) past->past_DeviceData;
#if PA_TRACE_START_STOP
    AddTraceMessage( "WinMMPa_OutputThreadProc: timeoutPeriod", timeoutPeriod );
    AddTraceMessage( "WinMMPa_OutputThreadProc: past_NumUserBuffers", past->past_NumUserBuffers );
#endif
/* Calculate timeOut as half the time it would take to play all buffers. */
	timeOut = (DWORD) (500.0 * PaHost_GetTotalBufferFrames( past ) / past->past_SampleRate);
/* Get event(s) ready for wait. */
    events[numEvents++] = pahsc->pahsc_BufferEvent;
    if( pahsc->pahsc_AbortEventInited ) events[numEvents++] = pahsc->pahsc_AbortEvent;
/* Stay in this thread as long as we are "active". */
    while( past->past_IsActive )
	{
/*******************************************************************/
/******** WAIT here for an event from WMME or PA *******************/
/*******************************************************************/
        waitResult = WaitForMultipleObjects( numEvents, events, FALSE, timeOut );
	/* Error? */
		if( waitResult == WAIT_FAILED )
		{
			sPaHostError = GetLastError();
			result = paHostError;
			past->past_IsActive = 0;
		}
	/* Timeout? Don't stop. Just keep polling for DONE.*/
		else if( waitResult == WAIT_TIMEOUT )
		{
#if PA_TRACE_START_STOP
	AddTraceMessage( "WinMMPa_OutputThreadProc: timed out ", numQueuedOutputBuffers );
#endif
			numTimeouts += 1;
		}
		/* Manage flags and audio processing. */
 		result = PaHost_BackgroundManager( past );
		if( result != paNoError )
		{
			past->past_IsActive = 0;
		}
	}
	return result;
}
#endif
/*******************************************************************/
PaError PaHost_OpenInputStream( internalPortAudioStream   *past )
{
	MMRESULT         mr;
	PaError          result = paNoError;
	PaHostSoundControl *pahsc;
	int              i;
	int              inputMmId;
	int              bytesPerInputFrame;
	WAVEFORMATEX     wfx;
	const PaDeviceInfo  *pad;
	pahsc = (PaHostSoundControl *) past->past_DeviceData;
	DBUG(("PaHost_OpenStream: deviceID = 0x%x\n", past->past_InputDeviceID));
	pad = Pa_GetDeviceInfo( past->past_InputDeviceID );
	if( pad == NULL ) return paInternalError;
	switch( pad->nativeSampleFormats  )
	{
		case paInt32:
		case paFloat32:
			bytesPerInputFrame = sizeof(float) * past->past_NumInputChannels;
			break;
		default:
			bytesPerInputFrame = sizeof(short) * past->past_NumInputChannels;
			break;
	}
	wfx.wFormatTag = WAVE_FORMAT_PCM;
	wfx.nChannels = (WORD) past->past_NumInputChannels;
	wfx.nSamplesPerSec = (DWORD) past->past_SampleRate;
	wfx.nAvgBytesPerSec = (DWORD)(bytesPerInputFrame * past->past_SampleRate);
	wfx.nBlockAlign = (WORD)bytesPerInputFrame;
	wfx.wBitsPerSample = (WORD)((bytesPerInputFrame/past->past_NumInputChannels) * 8);
	wfx.cbSize = 0;
	inputMmId = PaDeviceIdToWinId( past->past_InputDeviceID );
#if PA_USE_TIMER_CALLBACK
	mr = waveInOpen( &pahsc->pahsc_HWaveIn, inputMmId, &wfx,
	                  0, 0, CALLBACK_NULL );
#else
	mr = waveInOpen( &pahsc->pahsc_HWaveIn, inputMmId, &wfx,
	                  (DWORD)pahsc->pahsc_BufferEvent, (DWORD) past, CALLBACK_EVENT );
#endif
	if( mr != MMSYSERR_NOERROR )
	{
		ERR_RPT(("PortAudio: PaHost_OpenInputStream() failed!\n"));
		result = paHostError;
		sPaHostError = mr;
		goto error;
	}
/* Allocate an array to hold the buffer pointers. */
	pahsc->pahsc_InputBuffers = (WAVEHDR *) GlobalAlloc( GMEM_FIXED | GMEM_ZEROINIT, sizeof(WAVEHDR)*pahsc->pahsc_NumHostBuffers ); /* MEM */
	if( pahsc->pahsc_InputBuffers == NULL )
	{
		result = paInsufficientMemory;
		goto error;
	}
/* Allocate each buffer. */
	for( i=0; i<pahsc->pahsc_NumHostBuffers; i++ )
	{
		pahsc->pahsc_InputBuffers[i].lpData = (char *)GlobalAlloc( GMEM_FIXED, pahsc->pahsc_BytesPerHostInputBuffer ); /* MEM */
		if( pahsc->pahsc_InputBuffers[i].lpData == NULL )
		{
			result = paInsufficientMemory;
			goto error;
		}
		pahsc->pahsc_InputBuffers[i].dwBufferLength = pahsc->pahsc_BytesPerHostInputBuffer;
		pahsc->pahsc_InputBuffers[i].dwUser = i;
		if( ( mr = waveInPrepareHeader( pahsc->pahsc_HWaveIn, &pahsc->pahsc_InputBuffers[i], sizeof(WAVEHDR) )) != MMSYSERR_NOERROR )
		{
			result = paHostError;
			sPaHostError = mr;
			goto error;
		}
	}
	return result;
error:
	return result;
}
/*******************************************************************/
PaError PaHost_OpenOutputStream( internalPortAudioStream   *past )
{
	MMRESULT         mr;
	PaError          result = paNoError;
	PaHostSoundControl *pahsc;
	int              i;
	int              outputMmID;
	int              bytesPerOutputFrame;
	WAVEFORMATEX     wfx;
	const PaDeviceInfo *pad;
	pahsc = (PaHostSoundControl *) past->past_DeviceData;
	DBUG(("PaHost_OpenStream: deviceID = 0x%x\n", past->past_OutputDeviceID));
	pad = Pa_GetDeviceInfo( past->past_OutputDeviceID );
	if( pad == NULL ) return paInternalError;
	switch( pad->nativeSampleFormats  )
	{
		case paInt32:
		case paFloat32:
			bytesPerOutputFrame = sizeof(float) * past->past_NumOutputChannels;
			break;
		default:
			bytesPerOutputFrame = sizeof(short) * past->past_NumOutputChannels;
			break;
	}
	wfx.wFormatTag = WAVE_FORMAT_PCM;
	wfx.nChannels = (WORD) past->past_NumOutputChannels;
	wfx.nSamplesPerSec = (DWORD) past->past_SampleRate;
	wfx.nAvgBytesPerSec = (DWORD)(bytesPerOutputFrame * past->past_SampleRate);
	wfx.nBlockAlign = (WORD)bytesPerOutputFrame;
	wfx.wBitsPerSample = (WORD)((bytesPerOutputFrame/past->past_NumOutputChannels) * 8);
	wfx.cbSize = 0;
	outputMmID = PaDeviceIdToWinId( past->past_OutputDeviceID );
#if PA_USE_TIMER_CALLBACK
	mr = waveOutOpen( &pahsc->pahsc_HWaveOut, outputMmID, &wfx,
	                  0, 0, CALLBACK_NULL );
#else
	        
	pahsc->pahsc_AbortEvent = CreateEvent( NULL, TRUE, FALSE, NULL );
	if( pahsc->pahsc_AbortEvent == NULL )
	{
		result = paHostError;
		sPaHostError = GetLastError();
		goto error;
	}
	pahsc->pahsc_AbortEventInited = 1;
	mr = waveOutOpen( &pahsc->pahsc_HWaveOut, outputMmID, &wfx,
	                  (DWORD)pahsc->pahsc_BufferEvent, (DWORD) past, CALLBACK_EVENT );
#endif
	if( mr != MMSYSERR_NOERROR )
	{
		ERR_RPT(("PortAudio: PaHost_OpenOutputStream() failed!\n"));
		result = paHostError;
		sPaHostError = mr;
		goto error;
	}
/* Allocate an array to hold the buffer pointers. */
	pahsc->pahsc_OutputBuffers = (WAVEHDR *) GlobalAlloc( GMEM_FIXED | GMEM_ZEROINIT, sizeof(WAVEHDR)*pahsc->pahsc_NumHostBuffers ); /* MEM */
	if( pahsc->pahsc_OutputBuffers == NULL )
	{
		result = paInsufficientMemory;
		goto error;
	}
/* Allocate each buffer. */
	for( i=0; i<pahsc->pahsc_NumHostBuffers; i++ )
	{
		pahsc->pahsc_OutputBuffers[i].lpData = (char *) GlobalAlloc( GMEM_FIXED, pahsc->pahsc_BytesPerHostOutputBuffer ); /* MEM */
		if( pahsc->pahsc_OutputBuffers[i].lpData == NULL )
		{
			result = paInsufficientMemory;
			goto error;
		}
		pahsc->pahsc_OutputBuffers[i].dwBufferLength = pahsc->pahsc_BytesPerHostOutputBuffer;
		pahsc->pahsc_OutputBuffers[i].dwUser = i;
		if( (mr = waveOutPrepareHeader( pahsc->pahsc_HWaveOut, &pahsc->pahsc_OutputBuffers[i], sizeof(WAVEHDR) )) != MMSYSERR_NOERROR )
		{
			result = paHostError;
			sPaHostError = mr;
			goto error;
		}
	}
	return result;
error:
	return result;
}
/*******************************************************************/
PaError PaHost_GetTotalBufferFrames( internalPortAudioStream   *past )
{
	PaHostSoundControl *pahsc = (PaHostSoundControl *) past->past_DeviceData;
	return pahsc->pahsc_NumHostBuffers * pahsc->pahsc_FramesPerHostBuffer;
}
/*******************************************************************
* Determine number of WAVE Buffers
* and how many User Buffers we can put into each WAVE buffer.
*/
static void PaHost_CalcNumHostBuffers( internalPortAudioStream *past )
{
	PaHostSoundControl *pahsc = (PaHostSoundControl *) past->past_DeviceData;
	unsigned int  minNumBuffers;
	int           minFramesPerHostBuffer;
	int           maxFramesPerHostBuffer;
	int           minTotalFrames;
	int           userBuffersPerHostBuffer;
	int           framesPerHostBuffer;
	int           numHostBuffers;
/* Calculate minimum and maximum sizes based on timing and sample rate. */
	minFramesPerHostBuffer = (int) (PA_MIN_MSEC_PER_HOST_BUFFER * past->past_SampleRate / 1000.0);
	minFramesPerHostBuffer = (minFramesPerHostBuffer + 7) & ~7;
	DBUG(("PaHost_CalcNumHostBuffers: minFramesPerHostBuffer = %d\n", minFramesPerHostBuffer ));
	maxFramesPerHostBuffer = (int) (PA_MAX_MSEC_PER_HOST_BUFFER * past->past_SampleRate / 1000.0);
	maxFramesPerHostBuffer = (maxFramesPerHostBuffer + 7) & ~7;
	DBUG(("PaHost_CalcNumHostBuffers: maxFramesPerHostBuffer = %d\n", maxFramesPerHostBuffer ));
/* Determine number of user buffers based on minimum latency. */
	minNumBuffers = Pa_GetMinNumBuffers( past->past_FramesPerUserBuffer, past->past_SampleRate );
	past->past_NumUserBuffers = ( minNumBuffers > past->past_NumUserBuffers ) ? minNumBuffers : past->past_NumUserBuffers;
	DBUG(("PaHost_CalcNumHostBuffers: min past_NumUserBuffers = %d\n", past->past_NumUserBuffers ));
	minTotalFrames = past->past_NumUserBuffers * past->past_FramesPerUserBuffer;
/* We cannot make the WAVE buffers too small because they may not get serviced quickly enough. */
	if( (int) past->past_FramesPerUserBuffer < minFramesPerHostBuffer )
	{
		userBuffersPerHostBuffer =
			(minFramesPerHostBuffer + past->past_FramesPerUserBuffer - 1) /
			past->past_FramesPerUserBuffer;
	}
	else
	{
		userBuffersPerHostBuffer = 1;
	}
	framesPerHostBuffer = past->past_FramesPerUserBuffer * userBuffersPerHostBuffer;
/* Calculate number of WAVE buffers needed. Round up to cover minTotalFrames. */
	numHostBuffers = (minTotalFrames + framesPerHostBuffer - 1) / framesPerHostBuffer;
/* Make sure we have anough WAVE buffers. */
	if( numHostBuffers < PA_MIN_NUM_HOST_BUFFERS)
	{
		numHostBuffers = PA_MIN_NUM_HOST_BUFFERS;
	}
	else if( (numHostBuffers > PA_MAX_NUM_HOST_BUFFERS) && 
	         ((int) past->past_FramesPerUserBuffer < (maxFramesPerHostBuffer/2) ) )
	{
/* If we have too many WAVE buffers, try to put more user buffers in a wave buffer. */
		while(numHostBuffers > PA_MAX_NUM_HOST_BUFFERS)
		{
			userBuffersPerHostBuffer += 1;
			framesPerHostBuffer = past->past_FramesPerUserBuffer * userBuffersPerHostBuffer;
			numHostBuffers = (minTotalFrames + framesPerHostBuffer - 1) / framesPerHostBuffer;
	/* If we have gone too far, back up one. */
			if( (framesPerHostBuffer > maxFramesPerHostBuffer) ||
				(numHostBuffers < PA_MAX_NUM_HOST_BUFFERS) )
			{
				userBuffersPerHostBuffer -= 1;
				framesPerHostBuffer = past->past_FramesPerUserBuffer * userBuffersPerHostBuffer;
				numHostBuffers = (minTotalFrames + framesPerHostBuffer - 1) / framesPerHostBuffer;
				break;
			}
		}
	}
	
	pahsc->pahsc_UserBuffersPerHostBuffer = userBuffersPerHostBuffer;
	pahsc->pahsc_FramesPerHostBuffer = framesPerHostBuffer;
	pahsc->pahsc_NumHostBuffers = numHostBuffers;
	DBUG(("PaHost_CalcNumHostBuffers: pahsc_UserBuffersPerHostBuffer = %d\n", pahsc->pahsc_UserBuffersPerHostBuffer ));
	DBUG(("PaHost_CalcNumHostBuffers: pahsc_NumHostBuffers = %d\n", pahsc->pahsc_NumHostBuffers ));
	DBUG(("PaHost_CalcNumHostBuffers: pahsc_FramesPerHostBuffer = %d\n", pahsc->pahsc_FramesPerHostBuffer ));
	DBUG(("PaHost_CalcNumHostBuffers: past_NumUserBuffers = %d\n", past->past_NumUserBuffers ));
}
/*******************************************************************/
PaError PaHost_OpenStream( internalPortAudioStream   *past )
{
	PaError             result = paNoError;
	PaHostSoundControl *pahsc;
/* Allocate and initialize host data. */
	pahsc = (PaHostSoundControl *) PaHost_AllocateFastMemory(sizeof(PaHostSoundControl)); /* MEM */
	if( pahsc == NULL )
	{
		result = paInsufficientMemory;
		goto error;
	}
	memset( pahsc, 0, sizeof(PaHostSoundControl) );
	past->past_DeviceData = (void *) pahsc;
/* Figure out how user buffers fit into WAVE buffers. */
	PaHost_CalcNumHostBuffers( past );
	{
		int msecLatency = (int) ((PaHost_GetTotalBufferFrames(past) * 1000) / past->past_SampleRate);
		DBUG(("PortAudio on WMME - Latency = %d frames, %d msec\n", PaHost_GetTotalBufferFrames(past), msecLatency ));
	}
    InitializeCriticalSection( &pahsc->pahsc_StreamLock );
    pahsc->pahsc_StreamLockInited = 1;
	
#if (PA_USE_TIMER_CALLBACK == 0)
    pahsc->pahsc_BufferEventInited = 0;
    pahsc->pahsc_BufferEvent = CreateEvent( NULL, FALSE, FALSE, NULL );
    if( pahsc->pahsc_BufferEvent == NULL ){
        result = paHostError;
        sPaHostError = GetLastError();
        goto error;
    }
    pahsc->pahsc_BufferEventInited = 1;
#endif /* (PA_USE_TIMER_CALLBACK == 0) */
/* ------------------ OUTPUT */
	pahsc->pahsc_BytesPerUserOutputBuffer = past->past_FramesPerUserBuffer * past->past_NumOutputChannels * sizeof(short);
	pahsc->pahsc_BytesPerHostOutputBuffer = pahsc->pahsc_UserBuffersPerHostBuffer * pahsc->pahsc_BytesPerUserOutputBuffer;
	if( (past->past_OutputDeviceID != paNoDevice) && (past->past_NumOutputChannels > 0) )
	{
		result = PaHost_OpenOutputStream( past );
		if( result < 0 ) goto error;
	}
/* ------------------ INPUT */
	pahsc->pahsc_BytesPerUserInputBuffer = past->past_FramesPerUserBuffer * past->past_NumInputChannels * sizeof(short);
	pahsc->pahsc_BytesPerHostInputBuffer = pahsc->pahsc_UserBuffersPerHostBuffer * pahsc->pahsc_BytesPerUserInputBuffer;
	if( (past->past_InputDeviceID != paNoDevice) && (past->past_NumInputChannels > 0) )
	{
		result = PaHost_OpenInputStream( past );
		if( result < 0 ) goto error;
	}
/* Calculate scalar used in CPULoad calculation. */ 
	{
		LARGE_INTEGER frequency;
		if( QueryPerformanceFrequency( &frequency ) == 0 )
		{
			pahsc->pahsc_InverseTicksPerHostBuffer = 0.0;
		}
		else
		{
			pahsc->pahsc_InverseTicksPerHostBuffer = past->past_SampleRate /
				( (double)frequency.QuadPart * past->past_FramesPerUserBuffer * pahsc->pahsc_UserBuffersPerHostBuffer );
			DBUG(("pahsc_InverseTicksPerHostBuffer = %g\n", pahsc->pahsc_InverseTicksPerHostBuffer ));
		}
	}
	return result;
error:
	PaHost_CloseStream( past );
	return result;
}
/*************************************************************************/
PaError PaHost_StartOutput( internalPortAudioStream *past )
{
	MMRESULT         mr;
	PaHostSoundControl *pahsc;
	PaError          result = paNoError;
	int              i;
	pahsc = (PaHostSoundControl *) past->past_DeviceData;
    if( past->past_OutputDeviceID != paNoDevice )
	{
        if( (mr = waveOutPause( pahsc->pahsc_HWaveOut )) != MMSYSERR_NOERROR )
		{
			result = paHostError;
			sPaHostError = mr;
			goto error;
		}
        for( i=0; i<pahsc->pahsc_NumHostBuffers; i++ )
		{
            ZeroMemory( pahsc->pahsc_OutputBuffers[i].lpData, pahsc->pahsc_OutputBuffers[i].dwBufferLength );
            mr = waveOutWrite( pahsc->pahsc_HWaveOut, &pahsc->pahsc_OutputBuffers[i], sizeof(WAVEHDR) );
			if( mr != MMSYSERR_NOERROR )
			{
				result = paHostError;
				sPaHostError = mr;
				goto error;
			}
			past->past_FrameCount += pahsc->pahsc_FramesPerHostBuffer;
        }
        pahsc->pahsc_CurrentOutputBuffer = 0;
		if( (mr = waveOutRestart( pahsc->pahsc_HWaveOut )) != MMSYSERR_NOERROR )
		{
			result = paHostError;
			sPaHostError = mr;
			goto error;
		}
	}
	DBUG(("PaHost_StartOutput: DSW_StartOutput returned = 0x%X.\n", hr));
error:
	return result;
}
/*************************************************************************/
PaError PaHost_StartInput( internalPortAudioStream *past )
{
	PaError          result = paNoError;
	MMRESULT         mr;
	int              i;
	PaHostSoundControl *pahsc;
	pahsc = (PaHostSoundControl *) past->past_DeviceData;
    if( past->past_InputDeviceID != paNoDevice )
    {
        for( i=0; i<pahsc->pahsc_NumHostBuffers; i++ )
		{
            mr = waveInAddBuffer( pahsc->pahsc_HWaveIn, &pahsc->pahsc_InputBuffers[i], sizeof(WAVEHDR) );
			if( mr != MMSYSERR_NOERROR )
			{
				result = paHostError;
				sPaHostError = mr;
				goto error;
			}
        }
        pahsc->pahsc_CurrentInputBuffer = 0;
		mr = waveInStart( pahsc->pahsc_HWaveIn );
		DBUG(("Pa_StartStream: waveInStart returned = 0x%X.\n", hr));
		if( mr != MMSYSERR_NOERROR )
		{
			result = paHostError;
			sPaHostError = mr;
			goto error;
		}
	}
error:
	return result;
}
/*************************************************************************/
PaError PaHost_StartEngine( internalPortAudioStream *past )
{
	PaError             result = paNoError;
	PaHostSoundControl *pahsc = (PaHostSoundControl *) past->past_DeviceData;
#if PA_USE_TIMER_CALLBACK
	int                 resolution;
	int                 bufsPerTimerCallback;
	int                 msecPerBuffer;
#endif /* PA_USE_TIMER_CALLBACK */
	
    past->past_StopSoon = 0;
    past->past_StopNow = 0;
	past->past_IsActive = 1;
	pahsc->pahsc_FramesPlayed = 0.0;
	pahsc->pahsc_LastPosition = 0;
#if PA_TRACE_START_STOP
    AddTraceMessage( "PaHost_StartEngine: TimeSlice() returned ", result );
#endif
#if PA_USE_TIMER_CALLBACK
/* Create timer that will wake us up so we can fill the DSound buffer. */
	bufsPerTimerCallback = pahsc->pahsc_NumHostBuffers/4;
	if( bufsPerTimerCallback < 1 ) bufsPerTimerCallback = 1;
	if( bufsPerTimerCallback < 1 ) bufsPerTimerCallback = 1;
	msecPerBuffer = (1000 * bufsPerTimerCallback *
		pahsc->pahsc_UserBuffersPerHostBuffer *
		past->past_FramesPerUserBuffer ) / (int) past->past_SampleRate;
	if( msecPerBuffer < 10 ) msecPerBuffer = 10;
	else if( msecPerBuffer > 100 ) msecPerBuffer = 100;
	resolution = msecPerBuffer/4;
	pahsc->pahsc_TimerID = timeSetEvent( msecPerBuffer, resolution,
	                                     (LPTIMECALLBACK) Pa_TimerCallback,
	                                     (DWORD) past, TIME_PERIODIC );
	if( pahsc->pahsc_TimerID == 0 )
	{
		result = paHostError;
		sPaHostError = GetLastError();;
		goto error;
	}
#else /* PA_USE_TIMER_CALLBACK */
	ResetEvent( pahsc->pahsc_AbortEvent );
/* Create thread that waits for audio buffers to be ready for processing. */
	pahsc->pahsc_EngineThread = CreateThread( 0, 0, WinMMPa_OutputThreadProc, past, 0, &pahsc->pahsc_EngineThreadID );
	if( pahsc->pahsc_EngineThread == NULL )
	{
		result = paHostError;
		sPaHostError = GetLastError();;
		goto error;
	}
#if PA_TRACE_START_STOP
    AddTraceMessage( "PaHost_StartEngine: thread ", (int) pahsc->pahsc_EngineThread );
#endif
/* I used to pass the thread which was failing. I now pass GetCurrentProcess().
** This fix could improve latency for some applications. It could also result in CPU
** starvation if the callback did too much processing.
** I also added result checks, so we might see more failures at initialization.
** Thanks to Alberto di Bene for spotting this.
*/
    if( !SetPriorityClass( GetCurrentProcess(), HIGH_PRIORITY_CLASS ) ) /* PLB20010816 */
	{
		result = paHostError;
		sPaHostError = GetLastError();;
		goto error;
	}
    if( !SetThreadPriority( pahsc->pahsc_EngineThread, THREAD_PRIORITY_HIGHEST ) )
	{
		result = paHostError;
		sPaHostError = GetLastError();;
		goto error;
	}
#endif
error:
	return result;
}
/*************************************************************************/
PaError PaHost_StopEngine( internalPortAudioStream *past, int abort )
{
	int timeOut;
	PaHostSoundControl *pahsc = (PaHostSoundControl *) past->past_DeviceData;
	if( pahsc == NULL ) return paNoError;
/* Tell background thread to stop generating more data and to let current data play out. */
	past->past_StopSoon = 1;
/* If aborting, tell background thread to stop NOW! */
	if( abort ) past->past_StopNow = 1;
/* Calculate timeOut longer than longest time it could take to play all buffers. */
	timeOut = (DWORD) (1500.0 * PaHost_GetTotalBufferFrames( past ) / past->past_SampleRate);
	if( timeOut < MIN_TIMEOUT_MSEC ) timeOut = MIN_TIMEOUT_MSEC;
#if PA_USE_TIMER_CALLBACK
	if( (past->past_OutputDeviceID != paNoDevice) &&
		past->past_IsActive &&
		(pahsc->pahsc_TimerID != 0) )
	{
	/* Wait for IsActive to drop. */
		while( (past->past_IsActive) &&	(timeOut > 0) )
		{
			Sleep(10);
			timeOut -= 10;
		}
		timeKillEvent(pahsc->pahsc_TimerID);  /* Stop callback timer. */
		pahsc->pahsc_TimerID = 0;
	}
#else /* PA_USE_TIMER_CALLBACK */
#if PA_TRACE_START_STOP
    AddTraceMessage( "PaHost_StopEngine: thread ", (int) pahsc->pahsc_EngineThread );
#endif
    if( (past->past_OutputDeviceID != paNoDevice) &&
		(past->past_IsActive) &&
		(pahsc->pahsc_EngineThread != NULL) )
	{
		DWORD got;
/* Tell background thread to stop generating more data and to let current data play out. */
		DBUG(("PaHost_StopEngine: waiting for background thread.\n"));
        got = WaitForSingleObject( pahsc->pahsc_EngineThread, timeOut );
		if( got == WAIT_TIMEOUT )
		{
			ERR_RPT(("PaHost_StopEngine: timed out while waiting for background thread.\n"));
			return paTimedOut;
		}
		CloseHandle( pahsc->pahsc_EngineThread );
		pahsc->pahsc_EngineThread = NULL;
    }
#endif /* PA_USE_TIMER_CALLBACK */
	past->past_IsActive = 0;
	return paNoError;
}
/*************************************************************************/
PaError PaHost_StopInput( internalPortAudioStream *past, int abort )
{
	MMRESULT mr;
	PaHostSoundControl *pahsc = (PaHostSoundControl *) past->past_DeviceData;
	if( pahsc == NULL ) return paNoError;
	(void) abort;
    if( pahsc->pahsc_HWaveIn != NULL )
	{
		mr = waveInReset( pahsc->pahsc_HWaveIn );
		if( mr != MMSYSERR_NOERROR )
		{
			sPaHostError = mr;
			return paHostError;
		}
	}
	return paNoError;
}
/*************************************************************************/
PaError PaHost_StopOutput( internalPortAudioStream *past, int abort )
{
	MMRESULT mr;
	PaHostSoundControl *pahsc;
	pahsc = (PaHostSoundControl *) past->past_DeviceData;
	if( pahsc == NULL ) return paNoError;
	(void) abort;
#if PA_TRACE_START_STOP
    AddTraceMessage( "PaHost_StopOutput: pahsc_HWaveOut ", (int) pahsc->pahsc_HWaveOut );
#endif
   if( pahsc->pahsc_HWaveOut != NULL )
	{
		mr = waveOutReset( pahsc->pahsc_HWaveOut );
		if( mr != MMSYSERR_NOERROR )
		{
			sPaHostError = mr;
			return paHostError;
		}
	}
	return paNoError;
}
/*******************************************************************/
PaError PaHost_CloseStream( internalPortAudioStream   *past )
{
	int                 i;
	PaHostSoundControl *pahsc;
	if( past == NULL ) return paBadStreamPtr;
	pahsc = (PaHostSoundControl *) past->past_DeviceData;
	if( pahsc == NULL ) return paNoError;
#if PA_TRACE_START_STOP
    AddTraceMessage( "PaHost_CloseStream: pahsc_HWaveOut ", (int) pahsc->pahsc_HWaveOut );
#endif
/* Free data and device for output. */
    if( pahsc->pahsc_HWaveOut )
	{
        if( pahsc->pahsc_OutputBuffers )
		{
            for( i=0; i<pahsc->pahsc_NumHostBuffers; i++ )
			{
                waveOutUnprepareHeader( pahsc->pahsc_HWaveOut, &pahsc->pahsc_OutputBuffers[i], sizeof(WAVEHDR) );
                GlobalFree( pahsc->pahsc_OutputBuffers[i].lpData ); /* MEM */
            }
            GlobalFree( pahsc->pahsc_OutputBuffers ); /* MEM */
        }
        waveOutClose( pahsc->pahsc_HWaveOut );
    }
 /* Free data and device for input. */
   if( pahsc->pahsc_HWaveIn )
	{
        if( pahsc->pahsc_InputBuffers )
		{
            for( i=0; i<pahsc->pahsc_NumHostBuffers; i++ )
			{
                waveInUnprepareHeader( pahsc->pahsc_HWaveIn, &pahsc->pahsc_InputBuffers[i], sizeof(WAVEHDR) );
                GlobalFree( pahsc->pahsc_InputBuffers[i].lpData ); /* MEM */
            }
            GlobalFree( pahsc->pahsc_InputBuffers ); /* MEM */
        }
        waveInClose( pahsc->pahsc_HWaveIn );
    }
#if (PA_USE_TIMER_CALLBACK == 0)
    if( pahsc->pahsc_AbortEventInited ) CloseHandle( pahsc->pahsc_AbortEvent );
    if( pahsc->pahsc_BufferEventInited ) CloseHandle( pahsc->pahsc_BufferEvent );
#endif
	if( pahsc->pahsc_StreamLockInited )
	DeleteCriticalSection( &pahsc->pahsc_StreamLock );
	PaHost_FreeFastMemory( pahsc, sizeof(PaHostSoundControl) ); /* MEM */
	past->past_DeviceData = NULL;
	return paNoError;
}
/*************************************************************************
** Determine minimum number of buffers required for this host based
** on minimum latency. Latency can be optionally set by user by setting
** an environment variable. For example, to set latency to 200 msec, put:
**
**    set PA_MIN_LATENCY_MSEC=200
**
** in the AUTOEXEC.BAT file and reboot.
** If the environment variable is not set, then the latency will be determined
** based on the OS. Windows NT has higher latency than Win95.
*/
#define PA_LATENCY_ENV_NAME  ("PA_MIN_LATENCY_MSEC")
int Pa_GetMinNumBuffers( int framesPerBuffer, double sampleRate )
{
	char      envbuf[PA_ENV_BUF_SIZE];
	DWORD     hostVersion;
	DWORD     hresult;
	int       minLatencyMsec = 0;
	double    msecPerBuffer = (1000.0 * framesPerBuffer) / sampleRate;
	int       minBuffers;
/* Let user determine minimal latency by setting environment variable. */
	hresult = GetEnvironmentVariable( PA_LATENCY_ENV_NAME, envbuf, PA_ENV_BUF_SIZE );
	if( (hresult > 0) && (hresult < PA_ENV_BUF_SIZE) )
	{
		minLatencyMsec = atoi( envbuf );
	}
	else
	{
/* Set minimal latency based on whether NT or Win95.
 * NT has higher latency.
 */
		hostVersion = GetVersion();
/* High bit clear if NT */
		minLatencyMsec = ( (hostVersion & 0x80000000) == 0 ) ? PA_WIN_NT_LATENCY : PA_WIN_9X_LATENCY  ;
#if PA_USE_HIGH_LATENCY
		PRINT(("PA - Minimum Latency set to %d msec!\n", minLatencyMsec ));
#endif
	}
	DBUG(("PA - Minimum Latency set to %d msec!\n", minLatencyMsec ));
	minBuffers = (int) (1.0 + ((double)minLatencyMsec / msecPerBuffer));
	if( minBuffers < 2 ) minBuffers = 2;
	return minBuffers;
}
/*************************************************************************
** Cleanup device info.
*/
PaError PaHost_Term( void )
{
    int i;
    if( sNumDevices > 0 ){
        if( sDevicePtrs != NULL ){
            for( i=0; i<sNumDevices; i++ )
			{
                if( sDevicePtrs[i] != NULL )
				{
                    GlobalFree( (char*)sDevicePtrs[i]->name ); /* MEM */
                    GlobalFree( (void*)sDevicePtrs[i]->sampleRates ); /* MEM */
                    GlobalFree( sDevicePtrs[i] ); /* MEM */
                }
            }
            GlobalFree( sDevicePtrs ); /* MEM */
            sDevicePtrs = NULL;
        }
        sNumDevices = 0;
    }
    return paNoError;
}
/*************************************************************************/
void Pa_Sleep( long msec )
{
	Sleep( msec );
}
/*************************************************************************
 * Allocate memory that can be accessed in real-time.
 * This may need to be held in physical memory so that it is not
 * paged to virtual memory.
 * This call MUST be balanced with a call to PaHost_FreeFastMemory().
 * Memory will be set to zero.
 */
void *PaHost_AllocateFastMemory( long numBytes )
{
	void *addr = GlobalAlloc( GPTR, numBytes ); /* FIXME - do we need physical memory? Use VirtualLock() */ /* MEM */
	return addr;
}
/*************************************************************************
 * Free memory that could be accessed in real-time.
 * This call MUST be balanced with a call to PaHost_AllocateFastMemory().
 */
void PaHost_FreeFastMemory( void *addr, long numBytes )
{
	if( addr != NULL ) GlobalFree( addr ); /* MEM */
}
/***********************************************************************/
PaError PaHost_StreamActive( internalPortAudioStream   *past )
{
	PaHostSoundControl *pahsc;
	if( past == NULL ) return paBadStreamPtr;
	pahsc = (PaHostSoundControl *) past->past_DeviceData;
	if( pahsc == NULL ) return paInternalError;
	return (PaError) past->past_IsActive;
}
/*************************************************************************
 * This must be called periodically because mmtime.u.sample
 * is a DWORD and can wrap and lose sync after a few hours.
 */
static PaError PaHost_UpdateStreamTime( PaHostSoundControl *pahsc )
{
	MMRESULT  mr;
	MMTIME    mmtime;
	mmtime.wType = TIME_SAMPLES;
	if( pahsc->pahsc_HWaveOut != NULL )
	{
		mr = waveOutGetPosition( pahsc->pahsc_HWaveOut, &mmtime, sizeof(mmtime) );
	}
	else
	{
		mr = waveInGetPosition( pahsc->pahsc_HWaveIn, &mmtime, sizeof(mmtime) );
	}
	if( mr != MMSYSERR_NOERROR )
	{
		sPaHostError = mr;
		return paHostError;
	}
/* This data has two variables and is shared by foreground and background. */
/* So we need to make it thread safe. */
	EnterCriticalSection( &pahsc->pahsc_StreamLock );
		pahsc->pahsc_FramesPlayed += ((long)mmtime.u.sample) - pahsc->pahsc_LastPosition;
		pahsc->pahsc_LastPosition = (long)mmtime.u.sample;
    LeaveCriticalSection( &pahsc->pahsc_StreamLock );
	return paNoError;
}
/*************************************************************************/
PaTimestamp Pa_StreamTime( PortAudioStream *stream )
{
	PaHostSoundControl *pahsc;
	internalPortAudioStream   *past = (internalPortAudioStream *) stream;
	if( past == NULL ) return paBadStreamPtr;
	pahsc = (PaHostSoundControl *) past->past_DeviceData;
	PaHost_UpdateStreamTime( pahsc );
	return pahsc->pahsc_FramesPlayed;
}
